Pre-formed plug with inter-blade profiles for hydraulic turbines

ABSTRACT

The invention concerns an inter-blade profile (14) for a turbine runner blade, said inter-blade profile (14) comprising a profile (16), and a plug (18), forming a basis of the profile (16) and intended for being inserted into a corresponding hole (21) made in a blade.

RELATED APPLICATIONS

The present application is a Continuation application of U.S.application Ser. No. 16/527,615 filed Jul. 31, 2019, which claimedpriority to EP Application No. 18306071.4 filed Aug. 3, 2018, both ofwhich are incorporated by reference herein for all purposes.

DESCRIPTION Technical Field and Prior Art

The invention relates to the field of hydropower industry.

FIG. 1 illustrates a known turbine runner, comprising runner blades 2arranged between a crown 4 and a band 6. Each of these blades extendsbetween a leading edge 8 and a trailing edge 10 from which water flowsinto a draft tube (not shown on FIG. 1 ). The present applicationapplies not only to such turbines (Francis and others) and toturbine-pump runners possessing a crown and a band, but also to thosewith only a crown (propeller, or Kaplan, or diagonal flow and others).

Hollow inter-blade profiles 12 can be installed between blades in such ahydraulic turbine in order to provide aeration to the turbine flow. Moreprecisely, as explained in US 2016/0327012, air is injected into thewater flow in order to increase dissolved oxygen content in the waterflowing through the turbine. More precisely, each such hollowinter-blade profile provides an internal channel and aeration passageslocated in the profile surface for air to flow through from air channelsin the blade into the flowing water. Oxygen of the injected air is thentransferred to the oxygen depleted flowing water, increasing dissolvedoxygen levels as the air bubbles mix with the surrounding water.

Fabrication of such inter-blade profiles and their positioning on theblades present challenges.

The inter-blade profiles are fixed on the corresponding blades after therunner has been assembled: precise positioning of the inter-bladeprofile can be difficult to ensure and there is only limited work spacebetween runner blades for final assembly and finishing. Yet, they mustbe carefully positioned to prevent flow separations and cavitation dueto profiles that are hydraulically poorly oriented.

Another difficulty is that the geometry of a turbine runner is generallyfixed and cannot be modified without removing the turbine runner andreplacing it.

There is thus the problem of finding a new structure of inter-bladeprofiles and of blades enabling a simpler fabrication process of arunner.

There is also the problem of finding a process for reducing the numberof operations required by an operator who must work between runnerblades.

SUMMARY OF THE INVENTION

The present invention first concerns an inter-blade profile for aturbine runner blade, said inter-blade profile comprising a profile, anda plug, forming a basis of the profile.

Said plug is intended for being inserted into a corresponding hole madein a runner blade with an air channel. The inter-blade profile is thuspre-shaped on a plug that can be positioned in a corresponding hole onthe runner blade.

The plug, in cooperation with the hole, determines the position andorientation of the inter-blade profile in the correct orientation andimproves manufacturability and ease of assembly. Any possibility of poororientation is therefore avoided.

Use of a pre-machined inter-blade profile plug addresses thedifficulties mentioned above in connection with prior art turbinescomprising inter-blade profiles. In particular, use of a plug forinstalling the inter-blade profile ensures a single orientation of saidprofile and eliminates the possibility of misalignment.

Since the inter-blade profile has been designed to be well oriented tothe water flow, ensuring the profile can only be oriented in onedirection reduces the possibility of flow separations or cavitation thatmay occur when the profile is installed in the wrong orientation.

An inter-blade profile according to the invention can comprise at leastone zone, or fillet with at least one finite radius of curvature rbetween at least a lower part of the profile and at least part of anupper side of the plug, which reduces negative hydraulic phenomena, inparticular horseshoe vortex behaviour.

Said radius of curvature r can be variable along at least part of saidlower part of the profile and at least part of said upper side of theplug.

The shape of the inter-blade profile, including one or more zones withat least one finite radius of curvature r for reducing horseshoe vortexbehaviour, is thus pre-machined and reduces final assembly time andrisks of non-compliance with dimensional requirements.

Since such features are pre-fabricated on the plug and the profile,there is no need for a manual control during their fabrication betweentwo blades of a turbine runner, which eliminates manual operations insmall spaces.

An inter-blade profile according to the invention can comprise at leastone aeration passage, for example at least one slot and/or at least onehole through at least one of its lateral sides.

The aeration passage(s) can have complex geometries; access is notavailable or easy for machining such passages of an already installedinter-blade profile.

Furthermore, cleaning or maintaining or repairing such passages, and/orthe channel inside the profile and located behind said passages, isdifficult. Cleaning is in particular necessary when foreign materialshave passed through the aeration passages and are stuck in the channelbehind them, causing a reduction in the aeration potential of theturbine and reducing the dissolved oxygen levels in the tailrace belowthe power plant.

There is also the need to adapt the shape of these aeration passage(s)and/or of the inter-blade profile to new operating conditions of therunner. The geometry of a turbine runner is fixed and can be modifiedonly by removing the whole turbine runner and by replacing it (which isvery time consuming and very costly). Alternatively, machining theaeration passages without removing the whole turbine runner createsother difficulties because of the reduced space available for machiningand the need for specialised tools.

For the above reasons, in a preferred embodiment, an inter-blade profileaccording to the invention comprises at least one removable cover plate,said cover comprising at least one aeration passage, for example atleast one slot and/or at least one hole, and securing means, for exampleat least one hole for at least one screw or bolt, for securing saidremovable cover onto said inter-blade profile and demounting saidremovable cover from said inter-blade profile when needed.

A detailed machining of the removable cover plate, in particular of itsoutside surface, can be performed since this cover plate is readilyaccessible, thus increasing accuracy and reducing the risks ofnon-compliant machining.

Furthermore, long-term maintenance of the aeration passages and of theaeration channel, because the cover plate is removable, can befacilitated. There is much better access to the aeration channel whenthe cover plate is removed, making it easier to clean it and to removeany foreign materials that are too large to fit through the aerationpassages.

The removable cover-plate is smaller than the whole inter-blade profile,so that weight is not an issue and the cover plate can be removedwithout disassembling the turbine, reducing stoppage time.

This permits a replacement of a damaged cover plate or replacement of acover plate by a different cover plate having a different geometry, forexample a different geometry of the aeration passage(s) and/or of thehydraulic shape of the profile itself, not requiring a majorrehabilitation of the whole turbine.

Another advantage is that modifications of the geometry of the aerationpassages and/or of the inter-blade profile can be made directly on theremovable cover plate. Design improvements and modifications can beincorporated directly into the removable and replaceable cover platewithout requiring a major stoppage to remove and replace the turbinerunner.

The invention also concerns a runner blade, comprising a blade and atleast one inter-blade profile according to one of the above embodimentsof the invention.

Said at least one inter-blade profile and said blade can be assembled orjoined, for example welded, together.

The invention also concerns a method for fabricating a turbine runner,comprising runner blades arranged between a crown and a band orextending from a crown or from a central hub, at least one of saidrunner blades being according to the invention, said method comprisingassembling said blades with at least said crown or said central hub, andthen assembling said at least one blade according to the invention andat least one inter-blade profile according to the invention.

The invention also concerns a turbine runner, comprising runner blades,at least one of them according to the invention, said runner bladesbeing arranged between a crown and a band or said runner bladesextending from a crown or central hub.

The invention also concerns a method for fabricating a runner blade,comprising a blade and at least one inter-blade profile according to theinvention, said method comprising:

-   -   fabricating a blade comprising an air passage and at least one        hole adapted to contain the plug of said at least one        inter-blade profile;    -   positioning the plug of said inter-blade profile in said hole        and assembling said plug with said blade, for example by        welding.

A method according to the invention increases the manufacturability ofturbine runners.

The combination of a plug and a hole improves assembly by fixing theposition of the inter-blade profile prior to assembly. Features on theplug, such as pre-machined weld radii, reduces the time necessary toweld these features during final assembly and machining.

In the particular case where an inter-blade profile according to theinvention comprises an internal channel and a removable cover platecovering at least part of said internal channel or a runner bladecomprising such an inter-blade profile, said method comprising removingsaid removable cover plate and:

-   -   cleaning and/or maintaining and/or machining said internal        channel and/or at least one aeration passage of said removable        cover plate;    -   and/or replacing said removable cover plate with another        removable cover plate and/or machining at least one aeration        passage of said removable cover plate and fixing it again        against said inter-blade profile.

The advantages of a method according to the invention are in particularthose already mentioned above.

When the inter-blade profile itself is removable, said method accordingto the invention can further comprise a step of removing saidinter-blade profile from said blade, then removing said removable coverplate and performing one of the above steps.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 shows a hydroelectric turbine runner with inter-blade profiles,

FIGS. 2A-2C are different views of an inter-blade profile on a plug,according to the invention, before insertion into a corresponding holein a runner blade;

FIG. 2D shows different shapes of aeration passages that can beimplemented in the present invention, other geometries can however beconsidered

FIG. 3 illustrate a step of fabrication of a blade including a hole inorder to position therein a plug of an inter-blade profile according tothe invention;

FIG. 4 shows a single runner blade with an inter-blade profile accordingto the invention;

FIG. 5 illustrates inter-blade profiles on blades on a propeller hub;

FIGS. 6 and 7 illustrate an inter-blade profile incorporating aremovable plate with aeration slots.

DETAILED DISCLOSURE OF EMBODIMENTS

FIGS. 2A and 2B show lateral front views of an inter-blade profile 14according to the invention. FIG. 2C is an enlarged view of a part of theinter-blade profile 14. FIG. 2D shows alternative shapes of aerationpassages that can be implemented in the present invention. Othergeometries can however be considered.

The inter-blade profile 14 comprises a profile 16, delimited by 2lateral walls 16 i, 162, and a plug 18 (FIGS. 2A, 2B), forming a basisof the profile 16.

Said plug is intended to be inserted into a corresponding hole 21 madein the blade as illustrated on FIG. 3 . The profile 16 and the plug 18can be separately fabricated and then assembled or can be fabricated asone single piece.

The profile 16 has any shape adapted to the hydraulic requirements. Inparticular, it has at least one aeration passage, for example at leastone slot(s) 30 (FIG. 2A) and/or hole(s) through at least one of itswalls 16 ₁ and/or 16 ₂ for the circulation of air from the blade to thewater. For certain ranges of operating conditions of the turbine one ormore slots and/or holes can be located on both sides 16 ₁, 16 ₂ of theprofile. It can be noted that the aeration passage(s) can have otherpossible geometries: one or more straight line(s) (as on FIG. 2A), orseparated straight lines (ref 30 a on FIG. 2D), or comprising one ormore hole(s) (ref 30 b on FIG. 2D), or straight parallel lines (ref 30 con FIG. 2D), all these geometries of FIGS. 2A and 2D being possiblycombined. For example, the passage geometries can comprise any shapechosen among: round holes, straight slots, chevrons, stars, horseshoe,etc.

It shall be noted that the geometries previously mentioned orillustrated in FIG. 2D, do not limit the scope of the present inventionand the skill in the art can consider any other shape.

The plug substantially extends in a plane XZ (FIG. 2A) and has an upperside 20, turned to the profile itself and a lower side 22, which facesinside the blade after assembly of the inter-blade profile with theblade. It is limited by a contour or an outline having one lateral side23 on one side of the profile 16, and another lateral side 25 on theother side of the profile 16 (FIG. 2B). The contour can for example havea general oval shape.

The profile substantially extends in a plane XY (FIG. 2A; it thereforeextends substantially perpendicularly to the extension plane of theplug). It has in this XY plane a length or an extension L₁ (measuredalong axis X between the two most distant points of said profile) wherethe length of the profile at any section is smaller than the length orextension L₂ of the plug. As illustrated in FIG. 2A, the length of theprofile can vary in the y-direction. For example L₂ can be between 100mm and 700 mm; depending on the needs; for example L₂ can be about 500mm or close to 450 mm. Other values outside this range are possible. Theplug substantially extends in a plane XZ (FIG. 2A) perpendicularly toplane XY.

The profile has, along a Z axis which extends perpendicularly to planeXY (FIG. 2B), width l₁ (measured along axis Z between the two mostdistant points of said profile) where the width of the profile in anysection must be smaller than the width l₂ of the plug (measured alongaxis Z between the two most distant points of the lateral sides 23, 25of the plug). For example l₂ can be between 30 mm and 300 mm, dependingon the needs; for example l₂ can be about 50 mm or 100 mm. Other valuesoutside this range are possible.

The thickness of the profile is taken along the z direction. Saidthickness can vary along the height of the profile. For example thethickness can be longer at the base than at the top, or vice-versa. Thehydraulic shape of the profile can thus be constant or can vary alongthe height of the profile in length, thickness or shape.

The profile and its plug can be pre-shaped to have all the attributesnormally achieved after welding. In particular, fillets can be providedat the intersections 24, 26 of the profile and the upper side 20 of theplug. An example of such a fillet is shown on FIG. 2C: it forms a convexzone with a finite and possibly variable radius of curvature r betweenthe lower part of the profile and the upper side 20 of the plug. Thesefillets reduce negative hydraulic phenomena at the intersections 24, 26such as vortex flows and cavitation and help to reduce mechanicalstresses at the intersection of the two surfaces.

These fillets are pre-fabricated before assembly of the inter-bladeprofile with the blade, thus avoiding a manual control of the weldfillet radius during assembly between 2 neighbouring blades of analready assembled turbine, the space between such 2 neighbouring bladesbeing limited.

The plug is shown on FIGS. 2A-2D having flat upper and lower sides 20,22; however, it can have any other shape, adapted to the surface of theblade where the inter-blade profile is to be located.

As can be understood from FIG. 3 , a profile 16 and its plug 18 arefabricated separately from the blade 2. A hole 21 is made in the blade(to join the air channel in the blade to the hollow inter-blade profile,see FIG. 3 ) before the blade is mounted between a crown 4 and a band 6as on FIG. 1 so that the plug can be positioned and fixed (for example,but not limited to, welded, bolted, glued . . . ) therein. Preferably,the profile and its plug are assembled with the blade after the bladesare mounted between a crown 4 and a band 6 as on FIG. 1 , which is mucheasier than the difficult and unprecise positioning of the profileaccording to the prior art, which consists in positioning the profile(without plug) on the blade (without hole in the blade) and welding bothtogether in situ with the best possible (but necessarily unprecise)positioning. Alternatively, the profile and its plug are assembled withthe blade before the blades are mounted between the crown 4 and the band6, which is also much easier than according to the prior art.

The profile is hollow and an internal channel of the profilecommunicates through said hole 21 with a channel inside the blade forthe circulation of air through the blade, then through said internalchannel of the profile and then through at least one aeration passage inthe profile surface and finally into the flowing water.

The profile is fabricated with its plug. This can be done in a monobloc(as a single piece) or as a multi-piece assembly joining a base with aprofile. The plug has a shape that fits into the hole 21 made in theblade (see FIG. 3 ) so that it can be positioned and welded therein. Theweld seam around the plug (between the lateral sides 23, 25 of the plugand the hole) can be removed through grinding and polishing. Moreprecisely, the hole is slightly larger and longer than the plug, so thatthe plug and the blade can be easily welded together after the plug ispositioned inside the hole. The weld seam ensures water tightness andmechanical integrity of the assembled turbine runner.

Alternatively, the plug can be fixed to the blade by screwing orbolting, with help of screws or bolts and corresponding holes in theplug and in the blade, wherein one or more gaskets can be used for watertightness. This makes the mounting and dismounting of the plug easier.

FIG. 4 shows a runner blade 2 together with an inter-blade profile 14according to the invention. On this figure, the runner blade has onlyone profile according to the invention, however several profilesaccording to the invention can be assembled on a same blade on eitherthe suction or pressure sides of the blade.

A turbine runner according to the invention can comprise runner blades,at least one of them according to the invention, said runner bladesbeing arranged between a crown and a band like on FIG. 1 .

Alternatively, FIG. 5 shows runner blades 2 a mounted on a propeller hub4 a, each blade comprising an inter-blade profile 14 a according to theinvention, which extends from the suction side of a blade to thepressure side of the neighbouring blade.

Another aspect of the invention, which can be combined with one or moreof the above embodiments of an inter-blade profile, is illustrated onFIGS. 6 and 7 .

At least one part 160 of at least one lateral wall 161 or 162 of theinter-blade profile is removable. The other part of the inter-bladeprofile is fixed to the blade.

Said removable part 160, or cover plate, comprises one or more aerationpassage(s) 30, for example at least one slot(s) and/or hole(s), forproviding aeration to the water flow. Other shapes of aeration passagewere disclosed above in connection with FIGS. 2A and 2D and can beapplied to the aeration passages of a removable cover plate according tothis aspect of the invention. Other holes 161 (and corresponding holes163 in the fixed part of the profile, aligned with holes 161) are forsecuring the removable part 160 to the inter-blade profile with screws.Other securing means like bolts or adhesive material can be implemented.

FIG. 6 shows said removable cover plate 160 and the fixed part of saidinter-blade profile 14 before assembly and FIG. 7 shows both these partsassembled together.

Cover plate 160 is sufficiently small and the cover plate can be easilyremoved without disassembling the turbine, reducing stoppage time.

The cover plate can have a substantially square or rectangular shape asillustrated on FIG. 6 but other shapes can be implemented.

Removing said cover plate 160 from said inter-blade profile:

-   -   offers access to the aeration channel 162 (located behind the        cover plate) thus allowing cleaning and/or maintenance of said        aeration channel 162 and/or removal of any foreign materials        that are too large to fit through the aeration passages and are        stuck behind them;    -   and/or offers access to the aeration passage(s) 30, thus        allowing cleaning and/or maintenance of this/these aeration        passage(s) and/or of the outside and/or the inner surface of the        cover plate 160;    -   and/or allows modifications of the aeration passage(s) geometry        or of the geometry of the inter-blade profile itself (since the        cover plate itself forms part of the inter-blade profile, its        geometry is part of the geometry of the inter-blade profile).

The cover plate 160 can also be replaced with another removable parthaving for example different aeration slot(s) and/or hole(s).

Thus a damaged cover plate (for example a cover plate having damagedaeration passages) can be easily replaced or design improvements can beintegrated into the turbine design without requiring a major stoppage toremove and replace the turbine runner. These modifications can beincorporated directly into the removable and replaceable cover plate160.

The removable cover plate according to the above embodiments can also beadapted to profiles fabricated together with a blade according to knowntechniques: it is compatible with a profile mounted on a plug, asexplained above in connection with FIGS. 2A-3 , but also with a profilemade together with the blade (as illustrated on FIG. 1 ).

A runner can be fabricated, incorporating inter blade profiles, forexample according to the above embodiments disclosed in connection withFIGS. 2A to 3 . One or more removable cover plate(s) according to theabove embodiments can be installed on the thus finished runner, reducingmachining time.

1. A water turbine runner, comprising: a crown; a band; a plurality ofrunner blades arranged between the crown and the band; at least a firstone the runner blades comprising a hole in a sidewall thereof; aninter-blade profile extending transversely from the first runner blade,the inter-blade profile comprising: a profile component extendingtransversely from a plug, the plug forming a base insertable into thehole in the side wall of the first runner blade; the plug comprising anupper side that extends completely around and outwardly beyond theprofile component and lateral walls such that the upper side extendingaround the plug is exposed and flush with the side wall of the firstrunner blade and the lateral walls extend into the first runner blade;and wherein the hole in the side wall of the first runner blade matchesa shape of the plug so as to define a precise position and orientationof the inter-blade profile on the first runner blade.
 2. The waterturbine runner according to claim 1, wherein the inter-blade profilecomprises at least one zone with a finite radius of curvature (r)between a lower part of the profile component and the upper side of theplug.
 3. The water turbine runner according to claim 2, wherein theradius of curvature (r) is variable along at least part of the lowerpart of the profile component and at least part of the upper side of theplug.
 4. The water turbine runner according to claim 1, wherein theinter-blade profile comprises an internal channel and at least oneaeration passage in at least one side of the profile component.
 5. Thewater turbine runner according to claim 4, wherein the aeration passagecomprises at least one slot or hole through at least one side of theprofile component.
 6. The water turbine runner according to claim 1,wherein the inter-blade profile comprises a removable cover plate in alateral side of the profile component, the cover plate comprising atleast one aeration passage, and further comprising means for securingthe cover-plate onto the profile component.
 7. The water turbine runneraccording to claim 6, wherein the aeration passage comprises at leastone slot or hole through the cover plate.
 8. The water turbine runneraccording to claim 6, wherein the securing means comprises a screw holefor receipt of a screw therein.
 9. The water turbine runner according toclaim 1, wherein the plug of the inter-blade profile is fixed in thehole in the side wall of the first runner blade by one of welding;gluing, or bolting.
 10. A water turbine runner, comprising: a centralhub; a plurality of runner blades extending from the central hub; atleast a first one the runner blades comprising a hole in a sidewallthereof; an inter-blade profile extending transversely from the firstrunner blade, the inter-blade profile comprising: a profile componentextending transversely from a plug, the plug forming a base insertableinto the hole in the side wall of the first runner blade; the plugcomprising an upper side that extends completely around and outwardlybeyond the profile component and lateral walls such that the upper sideextending around the plug is exposed and flush with the side wall of thefirst runner blade and the lateral walls extend into the first runnerblade; and wherein the hole in the side wall of the first runner bladematches a shape of the plug so as to define a precise position andorientation of the inter-blade profile on the first runner blade. 11.The water turbine runner according to claim 10, wherein the inter-bladeprofile comprises at least one zone with a finite radius of curvature(r) between a lower part of the profile component and the upper side ofthe plug.
 12. The water turbine runner according to claim 11, whereinthe radius of curvature (r) is variable along at least part of the lowerpart of the profile component and at least part of the upper side of theplug.
 13. The water turbine runner according to claim 10, wherein theinter-blade profile comprises an internal channel and at least oneaeration passage in at least one side of the profile component.
 14. Thewater turbine runner according to claim 13, wherein the aeration passagecomprises at least one slot or hole through at least one side of theprofile component.
 15. The water turbine runner according to claim 10wherein the inter-blade profile comprises a removable cover plate in alateral side of the profile component, the cover plate comprising atleast one aeration passage, and further comprising means for securingthe cover-plate onto the profile component.
 16. The water turbine runneraccording to claim 15, wherein the aeration passage comprises at leastone slot or hole through the cover plate.
 17. The water turbine runneraccording to claim 15, wherein the securing means comprises a screw holefor receipt of a screw therein.
 18. The water turbine runner accordingto claim 10, wherein the plug of the inter-blade profile is fixed in thehole in the side wall of the first runner blade by one of welding;gluing, or bolting.